Method and system for a gas-tight cable feedthrough

ABSTRACT

A system includes a partition element and a first component which is arranged on a first side of the partition element. The first component includes at least one conductor, and the partition element includes an associated feedthrough for inserting and feeding through the conductor and for electrically contacting the conductor on a second side of the partition element located opposite the first side. The conductor forms a form-fitting connection to the feedthrough and is pressed into the feedthrough.

This application is a Continuation of U.S. application Ser. No.15/779,915, filed on May 30, 2018, which is a 371 of internationalapplication PCT/EP2016/078970, filed on Nov. 28, 2016, which claims thebenefit of DE 102015223910.1, filed on Dec. 1, 2015.

FIELD OF THE INVENTION

The present invention relates to a system comprising a first component,for example a stator winding or an electronics assembly, having aconductor and a partition element. The conductor is fed through thepartition element so as to electrically contact or be electricallyconnected to a second component on the other side. The inventionfurthermore relates to a method for producing the system.

TECHNICAL BACKGROUND

Known embodiments utilise methods in which a sealing medium isintroduced between the contact to be fed through and the design elementto be penetrated, which sealing medium is made of a polymer or a specialglass depending on the temperature, pressure and required mechanicalstrength. When a polymer is used, the pressure tightness at highpressures and the permeability to small gas molecules are unfavourable.The direct sealing solution using glass, is, in turn, complex anddifficult to implement using the production equipment of electronicsmanufacturing.

DE 198 52 730 C3 discloses an assembly comprising a holding part made ofelectrically insulating material and an electrical contact pin pottedtherein, which provides a gas-tight electrical connection through theholding part. The contact pin is provided at each of the two axial endsthereof with a connecting region. The connecting region forms theinterface to a component to be connected to the contact pins. Betweenthe connecting regions, the contact pin is provided with a securingregion, which ensures that the contact pin is anchored in the holdingpart, and a potting region, against which a potting compound rests,which rests against the holding part in a receiving region in the formof a borehole.

SUMMARY OF THE INVENTION

Against this background, the object of the present invention is toprovide a system having improved feedthrough of a conductor of acomponent through a partition element, for electrically contacting orconnecting to a component on the other side of the partition element.

According to the invention, this object is achieved by a systemincluding a partition element and a first component arranged on a firstside of the partition element. The first component includes at least oneconductor and the partition element includes an associated feedthroughfor feeding through the conductor and for electrically contacting orconnecting the conductor on a second side of the partition elementlocated opposite the first side. The conductor forms a form-fittingconnection to the feedthrough and being pressed into the feedthrough ofthe partition element.

The knowledge/concept on which the present invention is based is that ofconnecting a conductor of a component to a feedthrough of a partitionelement in a tight-fitting manner, the conductor being connected to thefeedthrough in a form-fitting manner and forming a press fit therewith.For this purpose, the feedthrough is designed in an undersized manner oras a press fit, and the conductor is cooled until the diameter of theconductor has shrunk sufficiently to insert and feed the conductor intoand through the feedthrough, so that the conductor can electricallycontact or be electrically connected to a second component on the otherside of the partition element.

This is advantageous in that a cost-effective and robust connectionbetween the conductor and the partition element can be provided and, atthe same time, a tight, in particular gas-tight, connection can beachieved.

Advantageous embodiments and developments can be derived from thefurther dependent claims and from the description with reference to thefigures in the drawings.

In one embodiment according to the invention, the feedthrough is athrough-hole, which forms a press fit together with the fed-throughconductor, the conductor, for insertion into and feeding through thefeedthrough, being previously cooled in a suitable manner so as toachieve sufficient shrinkage of the diameter thereof. In this way, theconductor can be joined to the partition element and the feedthroughthereof, and provide a tight, in particular gas-tight, connection to thepartition element.

In a further embodiment according to the invention, the conductor, forexample a copper conductor, is additionally aluminised on the outsidethereof, or connected, for example in a form-fitting manner, to analuminium sleeve or aluminium tube, at least in the region of thefeedthrough of the partition element. The aluminium sleeve or thealuminium tube can be made of aluminium or an aluminium alloy, or theconductor is provided with a coating made of aluminium or an aluminiumalloy, which may be anodised. Aluminising the conductor is advantageousin that the conductor is additionally anodised in locations where it isnot to be contacted and is not anodised in locations where it is to becontacted.

According to one embodiment according to the invention, the conductor isprovided with an oxide layer or anodised coating at least in the regionof the feedthrough of the partition element. The oxide layer or anodisedcoating is applied to the outside of the conductor or, in the case of apreviously aluminised conductor, to the aluminisation or coating made ofaluminium or an aluminium alloy. In the case of a form-fittingconnection between a conductor and an aluminium sleeve or aluminiumtube, for example for a conductor made of copper, the oxide layer oranodised coating is provided on the outside of the aluminium sleeve orthe aluminium tube. Such an oxide layer or anodised coating isadvantageous in that it provides a good insulator, which ischaracterised by mechanical scratch resistance and durability.

In a further embodiment according to the invention, the conductor ismade of an electrically conductive material or electrically conductivematerial combination, for example copper, a copper alloy, aluminiumand/or an aluminium alloy. Copper and aluminium and the alloys thereofare advantageous in that they are cost-effective and exhibit goodelectrical conductivity.

According to another embodiment according to the invention, thepartition element is made of metal, plastics material and/orfibre-reinforced plastics material. For example, the partition elementcan be made of steel, aluminium or an aluminium alloy, without beinglimited to these examples.

In one embodiment according to the invention, the at least one conductorof the first component is accommodated in a tight, in particularliquid-tight and/or gas-tight, manner, in the feedthrough of thepartition element, i.e. it is accommodated in a form-fitting manner andpressed in.

In a further embodiment according to the invention, the at least oneconductor can electrically contact or be electrically connected to asecond component on the second side of the partition element. The firstcomponent is an electrical winding, for example a stator winding, andthe second component is an electronics assembly, or vice versa.

According to another embodiment according to the invention, thetemperature of the at least one conductor is adjusted to the respectiveoperating temperature of the partition element. The diameter of theconductor expands so as to form a form-fitting connection to and a pressfit with the feedthrough of the partition element at all possibleoperating temperatures of the partition element and preferably of thefirst and second components connected or coupled to the partitionelement. This is advantageous in that, during operation of the system, atight-fitting, in particular liquid-tight and/or gas-tight, connectionis ensured between the conductor and the partition element, which hasthe feedthrough, and the partition element of said system and the firstcomponent of said system, which component can electrically contact or beelectrically connected to a second component.

The above embodiments and developments can be combined with one anotherin any way, provided this is meaningful. Additional possibleembodiments, developments and implementations of the invention alsoencompass not explicitly described combinations of features of theinvention described above or in the following with respect to theembodiments. In particular, a person skilled in the art will also addindividual aspects to the respective basic form of the present inventionas improvements or additions.

DESCRIPTION OF THE DRAWING

The present invention will be described in the following in greaterdetail on the basis of the embodiments provided in the schematic figuresof the drawings, in which:

FIG. 1 is a schematic view of two components that are electricallyconnected to one another by means of a plurality of conductors, in theform of feedthrough contacts, according to the invention, the twocomponents being separated from one another by a partition element;

FIG. 2 is a detail A of a conductor, in the form of a feedthroughcontact, and the feedthrough thereof through the partition elementaccording to FIG. 1;

FIG. 3 is the detail A according to FIG. 2, the conductor, in the formof a feedthrough contact, being made of drawn aluminium; and

FIG. 4 is a flow chart for producing a feedthrough according to theinvention of the contact through the partition element according toFIGS. 1, 2 and 3.

The accompanying drawings are intended to convey a further understandingof the embodiments of the invention. These illustrate embodiments and,in conjunction with the description, are provided to explain principlesand concepts of the invention. Other embodiments and many of theaforementioned advantages are apparent from the drawings. The elementsof the drawings are not necessarily to scale with respect to oneanother.

Unless stated otherwise, identical, functionally identical andidentically acting elements, features and components are in each casedenoted by identical reference numerals in the figures in the drawings.

DESCRIPTION OF EMBODIMENTS

FIG. 1 is a greatly simplified view of two components 1, 2 that areelectrically connected to one another by means of a plurality ofconductors 9 in the form of feedthrough contacts, the two components 1,2 being separated from one another by a partition element 4. Thepartition element 4, together with the first component 1 comprising theat least one conductor 9, forms a system according to the invention, inwhich the first component can electrically contact or be electricallyconnected to the second component 2 on the other side of the partitionelement 4 by means of the at least one conductor 9, the conductor beingaccommodated in a feedthrough 5 of the partition element 4 in a tight,in particular liquid-tight and preferably gas-tight, manner, as will bedescribed in greater detail in the following.

The conductor 9 can be provided as a pin. This applies to allembodiments of the invention. The contacts or feedthrough contacts thushave to be fed through the partition element 4 so as to electricallyconnect the two components 1, 2 to one another.

The feedthrough contacts are fed through the partition element 4 in sucha way that an electrically insulated and preferably tight, in particularliquid-tight and/or gas-tight, feedthrough 5 of the respectivefeedthrough contact through the partition element 4 is provided.

Such an electrically insulated and tight feedthrough 5, in particularliquid-tight and/or gas-tight feedthrough 5, of a respective feedthroughcontact through the partition element 4 is described in greater detailin the following on the basis of FIG. 2. FIG. 2 is detail A, which isindicated in FIG. 1 by a dotted line.

In FIG. 1, an electronics assembly 6 and a stator winding 7 are shown ina greatly simplified and purely schematic manner as examples of the twocomponents 1, 2 to be electrically connected, and are separated from oneanother by a housing wall 8 which serves as an example of a partitionelement 4. The housing wall can be made of metal, for example steel,aluminium or an aluminium alloy, and/or of plastics material,fibre-reinforced plastics material, etc., for example.

However, the invention is limited neither to an electronics assembly 6and a stator winding 7 as examples of components 1, 2 to be electricallyconnected to one another by at least one feedthrough contact 3, nor to ahousing wall 8 as an example of a partition element 4, or to a pluralityof feedthrough contacts, for example in the form of phase contacts.Instead, any component can be provided which can be electricallyconnected to another component by means of at least one contact orfeedthrough contact, the two components being separated from one anotherby a partition element through which the at least one contact orfeedthrough contact is to be fed.

FIG. 2 is a purely schematic and greatly simplified detail A of one ofthe contacts or feedthrough contacts shown in FIG. 1, and of thefeedthrough thereof through the partition element 4 according to FIG. 1.Detail A is shown in a sectional view in FIG. 2.

A conductor 9 of a component 1, in the form of a feedthrough-contact 3,is inserted through a feedthrough 5 in the partition element 4 from oneside of the partition element 4 and is fed through the feedthrough 5 soas to electrically contact another component 2 on the other side of thepartition element 4. The two components 1 and 2 are shown in FIG. 1. Inthe partition element 4 in the embodiment shown in FIG. 2, a cylindricalfeedthrough, for example a through-hole, is provided as the feedthrough5 for feeding through a corresponding conductor 9 having a circularcross-section. The invention is limited neither to a conductor 9, in theform of the feedthrough contact having a continuous circularcross-section, nor to a cylindrical feedthrough 5.

The conductor 9 to be fed through is made of drawn aluminium oraluminised copper, for example. Such a conductor 9 made of aluminisedcopper, in the form of the feedthrough contact, is shown in theembodiment in FIG. 2. In a conductor 9 made of aluminised copper, theconductor 9, in the form of a copper conductor 10, comprises a core madeof copper or a copper alloy and is, on the outside thereof, providedwith an additional aluminium coating 11 made of aluminium or analuminium alloy, as is shown in the embodiment in FIG. 2. Aluminisedcopper is advantageous in that it exhibits particularly goodconductivity and is therefore particularly well-suited where highconductivity is desirable. As a result of the aluminisation of thecopper conductor, an oxide layer or anodised coating 14, which isdescribed in the following, may subsequently be applied to the copperconductor or the aluminium coating 11 thereof, as shown in FIG. 2. Theoxide layer or anodised coating 14 has an electrically insulatingeffect. Such (an) oxide layer(s) or anodised coating(s) 14 can begenerated by means of anodic, electric oxidation, and produces aninsulating layer or layers that will adhere to aluminium or thealuminium coating 11. In contrast to aluminium or the aluminium coating11, copper itself cannot be anodised. Aluminium or the aluminium coating11 therefore has to be provided on the outside of a conductor made ofcopper, since only aluminium can be anodised.

In the case of an aluminium conductor made of drawn aluminium or a drawnaluminium alloy, in contrast, an additional coating made of aluminium oran aluminium alloy, as is the case for the copper conductor, is notprovided.

The invention, however, is limited neither to aluminium conductors norto additionally aluminised copper conductors. It is also possible toprovide any other metallic electrical conductor, which can preferably beprovided with an oxide layer or anodised coating.

The aluminisation or galvanic aluminisation of the conductor 9 to be fedthrough the partition element 4, which is a copper conductor here, canalso be provided, for example, only in a predetermined region of theconductor 9, for example a region of the conductor 9 to be kept free ofoxide, for example so as to ensure the conductor 9 contacts the othercomponent 2 in an oxide-free manner on the other side of the feedthrough5 or feedthrough point in the partition element 4. The aluminisation oraluminium coating 11 of the conductor 9, which is a copper conductorhere, can take place not only by means of galvanic aluminisation, butalso, for example, by connecting, in particular form-fittinglyconnecting, the conductor 9 to an aluminium sleeve or tube. For thispurpose, for example, a copper conductor is inserted into an aluminiumtube and, for example, at least the aluminium tube is drawn until aform-fitting connection between the copper conductor and the aluminiumtube is obtained. The aluminium tube in this case then forms thealuminium coating of the conductor 9, which is a copper conductor here,for example. The conductor is arranged coaxially in the aluminium tube.

Furthermore, the conductor 9, for example the aluminised copperconductor, together with the coating 11 thereof in the embodiment shownin FIG. 2, is provided with an additional coating 14. The additionalcoating 14 is provided on the outside of the conductor 9, and in theembodiment in FIG. 2 is provided on the outside of the first coating 11.

The additional coating 14 is located on the conductor 9 in what issubsequently the zone or the region 12 of the feedthrough 5 and is, asdescribed above, formed as an oxide layer or anodised coating, forexample made of aluminium or an aluminium alloy. The additional coating14 is applied to the conductor 9, or the first coating 11 thereof, byanodisation, for example. Anodising is a generally known method forfinishing aluminium or aluminium alloy surfaces. This is an anodictreatment since the material is electrochemically oxidised in a bath.The oxide layer or anodised coating, in the form of the coating 14, is agood insulator, which is characterised by mechanical scratch resistanceand durability. The invention, however, is not limited to an oxide layeror anodised coating, in the form of the coating 14. It is possible toprovide any other suitable electrically insulating and mechanicallyresistant coating.

The two coatings 11 and 14, however, are optional and may also bedispensed with and replaced with coatings having comparable properties.This applies to all embodiments of the invention.

In the production of the feedthrough 5, in particular the cylindricalfeedthrough or through-hole, for the conductor 9 in the partition wall4, a certain diameter of the feedthrough 5 is maintained. Suitablemeasures may be provided to maintain the diameter of the feedthrough 5.For this purpose, the material to be penetrated is provided with anundersized borehole or press fit in the following so as to accommodateand feed the conductor 9 through as a feedthrough contact.

The conductor 9, in the form of a through-contact, is cooled compared tothe partition element 4 prior to joining. For cooling, a suitable agent,for example liquid nitrogen, may be used. The conductor 9, in the formof a feedthrough contact, is cooled such that the diameter thereofshrinks, and the shrinkage of the size thereof allows joining into theundersized feedthrough 9, which is the undersized through-hole here, inthe partition element 4. During the subsequent adjustment of thetemperature of the conductor 9 to the temperature of the partitionelement 4, the conductor 9, in the form of the feedthrough contact, ispressed into the through-hole of the partition element 4, and, due tothe ductile properties of the conductor core 13 thereof, made ofaluminium, an aluminium alloy or copper, for example, is able to adaptto the material of the partition element 4 to be penetrated, for examplethe housing wall 8 in the embodiment in FIGS. 1 and 2. The oxide layeror anodised coating, in the form of the additional coating 14, is a hardand insulating layer, provided it has not been compressed.

The form fit with the partition element 4, or the form-fittingconnection between the conductor 9 and the partition element 4, achievedby means of the shrinkage process and the subsequent expansion processof the conductor 9, allows sufficient or suitable liquid tightness andin particular gas tightness of the feedthrough of the conductor 9through the partition element 4 to be achieved.

FIG. 3 is the detail A according to FIG. 2; however the conductor, inthe form of a feedthrough contact, is made of drawn aluminium.

The embodiment shown in FIG. 3 has the same construction and the sameprocedure as the embodiment shown in FIG. 2, and so reference is made inthis regard to the comments provided in FIGS. 1 and 2 to avoidunnecessary repetition. The embodiment shown in FIG. 3 differs from theembodiment shown in FIG. 2 only in that the conductor 9 in FIG. 3 is analuminium conductor made of aluminium or an aluminium alloy and is notadditionally aluminised. In contrast to the embodiment in FIG. 2, theconductor 9 accordingly comprises on the outside thereof, at least inthe region of the feedthrough 5 through the partition element 4, onlythe oxide layer or anodised coating as the additional coating 14.

FIG. 4 shows an embodiment of a flow chart for producing a feedthroughaccording to the invention of a conductor, in the form of a feedthroughcontact of a first component through a partition element for theelectrical connection to a second component on the opposite side of thepartition element, as was shown above by way of example with referenceto FIGS. 1, 2 and 3.

In a first step S1, the first component comprising at least oneconductor is provided, the conductor being made of an electricallyconductive material, for example an aluminium conductor, or at leastcomprises a core made of an electrically conductive material, such as acopper conductor, as shown in FIG. 2.

In the case of a copper conductor, this is aluminised in an optionalstep S1* and provided with an additional coating made of aluminium or analuminium alloy on the outside thereof, at least in the region of thefeedthrough of the conductor through the partition element, so as toenable subsequent anodisation for electrical insulation. In the case ofan aluminium conductor, for example made of drawn aluminium or analuminium alloy, an additional aluminisation of the conductor by meansof this coating can be dispensed with and instead an oxide layer oranodised coating can be applied directly in a next step S1**, at leastin the region of the feedthrough of the aluminium conductor through thepartition element.

In the next step S1**, the conductor, which is the aluminium conductorhere, or in the case of the copper conductor the aluminised regionthereof, is provided with an additional oxide layer or anodised coating,in particular an oxide layer or anodised coating made of aluminium or analuminium alloy. The conductor can be an aluminium conductor made ofdrawn aluminium or an aluminium alloy, for example, as shown in FIG. 3,or an aluminised copper conductor, as shown in FIG. 2, or a copperconductor connected in a form-fitting manner to an aluminium sleeve ortube.

In a step S2, the partition element is provided with a feedthrough, forexample a through-hole, the feedthrough being provided in an undersizeddimension.

Thereupon, in a step S3, the conductor or at least the portion of theconductor to be fed through the partition element and the feedthroughthereof are cooled such that the diameter of the conductor shrinks to asuitable degree, so as to be able to be joined into the undersizedfeedthrough 5.

In a subsequent step S4, the temperature of the conductor is adjusted tothe temperature, in particular the operating temperature, of thepartition element, the conductor, in the form of a feedthrough contact,being pressed into the feedthrough of the partition element and,together with the oxide layer or anodised coating thereof, forming atight, in particular liquid-tight and preferably a gas-tight, connectionto the feedthrough at the operating temperature or in an operatingtemperature range of the partition element.

Although the present invention was described above in full on the basisof preferred embodiments, it is not limited to these, but may bemodified in a variety of ways. In particular, the individualembodiments, as they were described with reference to FIGS. 1 to 4, canalso be combined with one another, in particular individual featuresthereof.

LIST OF REFERENCE NUMERALS

1 component

2 component

4 partition element

5 feedthrough

6 electronics assembly

7 stator winding

8 housing wall

9 conductor

10 copper conductor

11 coating

12 region

13 conductor core

14 oxide layer or anodised coating

The invention claimed is:
 1. A system comprising: a partition element;and a first component which is arranged on a first side of the partitionelement, wherein the first component comprises at least one conductor,and the partition element comprises an associated feedthrough forinserting and feeding through the conductor and for electricallycontacting the conductor on a second side of the partition elementlocated opposite the first side, wherein the conductor forms aform-fitting connection to the feedthrough and is pressed into thefeedthrough, wherein the conductor, at least in the region of thefeedthrough of the partition element, is provided with an oxide layer oranodised coating.
 2. A system comprising: a partition element; and afirst component which is arranged on a first side of the partitionelement, wherein the first component comprises at least one conductor,and the partition element comprises an associated feedthrough forinserting and feeding through the conductor and for electricallycontacting the conductor on a second side of the partition elementlocated opposite the first side, wherein the conductor forms aform-fitting connection to the feedthrough and is pressed into thefeedthrough, wherein the feedthrough is a through-hole which forms apress fit with the inserted and fed-through conductor, a diameter of theconductor being previously shrunk by means of cooling for the insertionand feeding-through in the feedthrough.
 3. The system according to claim1, wherein the conductor, at least in a region of the feedthrough of thepartition element, is aluminised on an outside thereof and is preferablyprovided with a coating made of aluminium or an aluminium alloy orconnected in a form-fitting manner to an aluminium sleeve or analuminium tube.
 4. The system according to claim 3, wherein the oxidelayer or anodised coating is applied to the outside of the conductor or,in the case of an aluminised conductor, is applied to the aluminisedoutside of the conductor with a coating made of aluminium or analuminium alloy, an aluminium sleeve or an aluminium tube of thealuminised conductor.
 5. The system according to claim 1, wherein theconductor is made of an electrically conductive material or electricallyconductive material combination.
 6. The system according to claim 1,wherein the partition element is made of metal, a metal alloy, plasticsmaterial and/or fibre-reinforced plastics material.
 7. The systemaccording to claim 1, wherein the conductor is accommodated in thefeedthrough of the partition element in a tight, in particular in aliquid-tight and/or gas-tight, manner.
 8. The system according to claim1, wherein the conductor is constructed and arranged to electricallycontact a second component on the second side of the partition element,the first component being an electrical winding, and the secondcomponent being an electronics assembly, or vice versa.
 9. The systemaccording to claim 5, wherein the conductor is made of copper, a copperalloy, aluminium and/or an aluminium alloy.